SU548638A1 - Furnace with a fine heat carrier - Google Patents

Description

one

The invention relates to the field of heat treatment of products and can be used in the metallurgical and engineering industries.

It is known a device comprising its body, iodine (gas distribution grid) and a fine layer, in which the countercurrent can be carried out by applying vibration to below 1.

However, in industrial installations it is difficult to obtain uniform hydrodynamics, since due to the redistribution of particles with different specific gravities and different sizes in the layer, uneven dimensional layer density and entrainment of the fine fraction are observed. The need to vibrate the chamber in which the fine heat carrier is located increases the energy consumption. In addition, this device has a small range of use of frequencies and amplitudes of oscillations.

The aim of the invention is to increase the intensity of the heat treatment process during countercurrent movement of the products and the coolant.

This is achieved by the fact that, in the proposed device, the device is designed in the form of discs arranged in a closed contour, where on the upper surface of each is reinforced with a base a l-shaped plate at an angle to the horizontal and vertical axis of the disk,

In order to reduce burnout and warping of the disks, their surface is made of ribbed.

FIG. 1 shows the proposed furnace, longitudinal section; in fig. 2-sections along A-A and B-B of FIG. one; in fig. 3-disc with a ledge; in fig. 4-disc, top view.

The furnace consists of corus 1, a fine heat carrier 2, disks 3 with L-shaped plates 4 fixed on their upper surface 4, hearth 5, sublattice space 6, and a direct device 7, a heater and processed products 8.

The furnace has a heating zone 9, a heating zone 10, a cooling zone of 11 products.

The furnace works as follows.

A layer of dispersed material is poured into the body (for example, magnesite of a fraction of 0.1–0.2 mm) and the disks, which are held in a closed loop, are set into rotation. The L-shaped plate is firmly fixed to the base of the outer surface of the disk along its radius and at an angle to the horizontal and vertical axis, the direction of the angle of inclination of the plate opposite to the direction of rotation of the disk, and the top-n part of the plate is parallel to the Danish. When inserting discs with plates, each part of the layer alternately and periodically tosses up and simultaneously rotates, i.e.

a vibrating fluidized rotating bed is obtained.

The upper part of the L-shaped plate is made parallel to the plane of the disk in order to increase the slot time and thereby obtain large amplitudes in the upper part of the vibrating bed, which increases the heat transfer coefficients. Due to the friction of the particles of the wall layer and the vortex motion of the gas phase, large relative velocities (relative to the axis of rotation) are obtained, ensuring high heat transfer coefficients.

When the disks with L-shaped plates are rotated in one direction, the directional circulation of the layer particles from one treatment zone to another is achieved.

The processed products (for example, wire, tape, etc.) along the guide) at the beginning enter the heating zone, where they are heated by the heat carried by the heat carrier particles moving from the heating zone. In the heating zone, the products are heated to the actual process temperature. Heat is supplied in the heating zone in one of the known methods (nanometer, electrical heating).

In the heating zone, the working surface of the disks is finned. When the discs rotate, the intercostal space is filled with dispersed material. The ribs serve d; 1 retention of dispersed material on the surface of the disk. Due to this disc design, their working surface is zaischea from direct contact with a hot coolant.

Further, the products are transported from the heating zone to the cooled zone, where they transfer accumulated heat to the heat transfer particles moving towards them, and the products are cooled, and the heat carrier is heated before entering the heating zone.

Thus, in the working space of the proposed RCP, the continuous movement of the coolant towards the moving workpiece is in progress and, therefore, the products are heated in countercurrent mode.

Claims (2)

1. An oven with a finely dispersed coolant, comprising a housing with heaters, having the possibility of not displacing the lattice subsurface and a gas pipeline, characterized by the fact that, in order to increase the intensity of the heat treatment process during countercurrent movement of the products and the coolant, iodine is made in the form of discs located in a closed circuit on the upper surface each of which is rigidly fixed by the base of the l-shaped plate at an angle to the horizontal and vertical axis of the disk. 2. Bake pop 1, characterized in that, in order to reduce burnout and warping of the disks, their surface is ribbed. Source 1P format, taken into account during examination: 1. Cheese tnikov N. And. And others. Thermal ironess B furnaces with a fluidized bed. M., Metallurgp, 1968, e. 30, fig. 11 (prototype). I J  T- 4 1 Rig.